Robotic end effector with adjustable inner diameter

ABSTRACT

An end effector for a surgical robotic system, comprising a main body, one or members, and an adjustment mechanism. The main body has an interior sidewall and an opening extending through the main body. The one or more members are located within the main body and extend into and retract from the opening to vary a diameter of the opening through which a tool may be inserted. The adjustment mechanism coupled to the one or more members for varying the diameter of the opening, and comprises a collar coupled to the one or more members such that rotation of the collar in a first direction causes the one or more members to move away from the interior sidewall to reduce the diameter of the opening, and rotation in a second direction causes the one or more members to move towards the interior sidewall to increase the diameter of the opening.

CROSS-REFERENCE TO RELATED APPLICATIONS

The subject patent application is a Continuation of U.S. patentapplication Ser. No. 15/928,668, filed on Mar. 22, 2018, which claimspriority to all the benefits of U.S. Provisional Patent Application No.62/475,281, filed Mar. 23, 2017, the disclosures of each of which arehereby incorporated by reference in their entirety.

BACKGROUND

Surgical procedures, such as minimally-invasive procedures, may requirea surgeon to insert surgical tools inside the body of the patient to aparticular depth to reach the target area inside the patient's body. Forexample, minimally invasive spinal surgical procedures have been usedfor stabilization of vertebral bones and spinal joints and for relievingof pressure applied to the spinal nerves. Such procedures may utilizerelatively small incisions and insertion of tubular retractors andcannulas while minimizing damage to muscles and other surroundinganatomical features. Minimally invasive surgical approaches can befaster, safer and require less recovery time than conventional opensurgeries. There is a continuing need for improvement to the safety andspeed of surgical procedures, such as minimally-invasive surgicalprocedures.

SUMMARY

Various embodiments include an end effector for a robotic-assistedsurgical system that has an adjustable inner diameter. In embodiments,an end effector includes a main body having an opening extending throughthe main body, one or more members located within the main body thatextend into and retract from the opening to vary a diameter of theopening through which a tool may be inserted, and an adjustmentmechanism on the end effector and coupled to the one or more members forvarying the diameter of the opening.

Further embodiment include a method of inserting a tool into the body ofa patient that includes positioning an end effector over the body of thepatient such that an opening extending through the end effector definesa trajectory into the body of the patient, using an adjustment mechanismto vary a size of a working channel through the opening of the endeffector such that the diameter of the working channel corresponds withan outer diameter of the tool, and inserting the tool through theworking channel of the end effector along the defined trajectory andinto the body of the patient.

BRIEF DESCRIPTION OF THE DRAWINGS

Other features and advantages of the present invention will be apparentfrom the following detailed description of the invention, taken inconjunction with the accompanying drawings of which:

FIG. 1 illustrates a robotic-assisted surgical system for use with anadjustable diameter end effector according to an embodiment.

FIG. 2 is a perspective view of an end effector according to anembodiment.

FIG. 3 is a side elevation view of the end effector shown in FIG. 2 .

FIG. 4 is a rear elevation view of the end effector shown in FIG. 2 .

FIG. 5 is a partial cross-section view of an embodiment end effectorviewed along line A-A in FIG. 4 .

FIGS. 6A-6C are top views of an end effector illustrating a plurality ofmoveable flutes in different configurations to provide a central openinghaving a varying diameter.

DETAILED DESCRIPTION

The various embodiments will be described in detail with reference tothe accompanying drawings. Wherever possible, the same reference numberswill be used throughout the drawings to refer to the same or like parts.References made to particular examples and implementations are forillustrative purposes, and are not intended to limit the scope of theinvention or the claims.

Various embodiments include an end effector for a robotic arm thatincludes a hollow tube or cannula through which one or more tools, suchas an invasive surgical tool, may be inserted. The end effectoraccording to various embodiments may have an adjustable inner diameterto enable tools of different sizes to be accurately guided through theinterior of the end effector.

FIG. 1 illustrates a system 100 for performing computer-assistedimage-guided surgery that may utilize an end effector 102 having anadjustable inner diameter according to various embodiments. The system100 in this embodiment includes an imaging device 103, a motion trackingsystem 105 and a robotic arm 101 for performing a robotically-assistedsurgical procedure. The robotic arm 101 may be fixed to a supportstructure at one end and may have an adjustable-diameter end effector102 located at the other end of the robotic arm 101. The robotic arm 101may comprise a multi-joint arm that includes a plurality of linkagesconnected by joints having actuator(s) and optional encoder(s) to enablethe linkages to rotate, bend and/or translate relative to one another inresponse to control signals from a robot control system. The motions ofthe robotic arm 101 may enable the end effector 102 to be moved tovarious positions and/or orientations, such as various positions and/ororientations with respect to a patient (not illustrated) that may belocated on a patient support 60 (e.g., surgical table).

The imaging device 103 may be used to obtain diagnostic images of apatient (not shown in FIG. 1 ), which may be a human or animal patient.In embodiments, the imaging device 103 may be an x-ray computedtomography (CT) imaging device. The patient may be positioned within acentral bore 107 of the imaging device 103 and an x-ray source anddetector may be rotated around the bore 107 to obtain x-ray image data(e.g., raw x-ray projection data) of the patient. The collected imagedata may be processed using a suitable processor (e.g., computer) toperform a three-dimensional reconstruction of the object. In otherembodiments, the imaging device 103 may comprise one or more of an x-rayfluoroscopic imaging device, a magnetic resonance (MR) imaging device, apositron emission tomography (PET) imaging device, a single-photonemission computed tomography (SPECT), or an ultrasound imaging device.In embodiments, image data may be obtained pre-operatively (i.e., priorto performing a surgical procedure), intra-operatively (i.e., during asurgical procedure) or post-operatively (i.e., following a surgicalprocedure) by positioning the patient within the bore 107 of the imagingdevice 103. In the system 100 of FIG. 1 , this may be accomplished bymoving the imaging device 103 over the patient to perform a scan whilethe patient may remain stationary.

Examples of x-ray CT imaging devices that may be used according tovarious embodiments are described in, for example, U.S. Pat. No.8,118,488, U.S. Patent Application Publication No. 2014/0139215, U.S.Patent Application Publication No. 2014/0003572, U.S. Patent ApplicationPublication No. 2014/0265182 and U.S. Patent Application Publication No.2014/0275953, the entire contents of all of which are incorporatedherein by reference. In the embodiment shown in FIG. 1 , the patientsupport 60 (e.g., surgical table) upon which the patient may be locatedis secured to the imaging device 103, such as via a column 50 which ismounted to a base 20 of the imaging device 103. A portion of the imagingdevice 103 (e.g., an O-shaped imaging gantry 40) which includes at leastone imaging component may translate along the length of the base 20 onrails 23 to perform an imaging scan of the patient, and may translateaway from the patient to an out-of-the-way position for performing asurgical procedure on the patient. It will be understood that otherimaging devices may be utilized, including other mobile or fixed x-rayCT devices or a C-arm x-ray fluoroscopy device.

Further, although the imaging device 103 shown in FIG. 1 is locatedclose to the patient within the surgical theater, the imaging device 103may be located remote from the surgical theater, such as in another roomor building (e.g., in a hospital radiology department).

The motion tracking system 105 shown in FIG. 1 includes a plurality ofmarker devices 119, 202 and an optical sensor device 111. Varioussystems and technologies exist for tracking the position (includinglocation and/or orientation) of objects as they move within athree-dimensional space. Such systems may include a plurality of activeor passive markers fixed to the object(s) to be tracked and a sensingdevice that detects radiation emitted by or reflected from the markers.A 3D model of the space may be constructed in software based on thesignals detected by the sensing device.

The motion tracking system 105 in the embodiment of FIG. 1 includes aplurality of marker devices 119, 202 and a stereoscopic optical sensordevice 111 that includes two or more cameras 207 (e.g., IR cameras). Theoptical sensor device 111 may include one or more radiation sources(e.g., diode ring(s)) that direct radiation (e.g., IR radiation) intothe surgical field, where the radiation may be reflected by the markerdevices 119, 202 and received by the cameras. The marker devices 119,202 may each include three or more (e.g., four) reflecting spheres,which the motion tracking system 105 may use to construct a coordinatesystem for each of the marker devices 119, 202. A computer 113 may becoupled to the sensor device 111 and may determine the transformationsbetween each of the marker devices 119, 202 and the cameras using, forexample, triangulation techniques. A 3D model of the surgical space in acommon coordinate system may be generated and continually updated usingmotion tracking software implemented by the computer 113. Inembodiments, the computer 113 may also receive image data from theimaging device 103 and may register the image data to the commoncoordinate system as the motion tracking system 105 using imageregistration techniques as are known in the art. In embodiments, atleast one reference marker device 115 may be attached to the patient200, as shown in FIGS. 2A-2C. The reference marker device 115 may berigidly attached to a landmark in the anatomical region of interest(e.g., clamped or otherwise attached to a bony portion of the patient'sanatomy) to enable the anatomical region of interest to be continuallytracked by the motion tracking system 105. Additional marker devices 119may be attached to surgical tools or instruments 104 to enable thetools/instruments 104 to be tracked within the common coordinate system.Another marker device 202 may be rigidly attached to the robotic arm101, such as on the end effector 102 of the robotic arm 101, to enablethe position of robotic arm 101 and end effector 102 to be tracked usingthe motion tracking system 105. The computer 113 may also includesoftware configured to perform a transform between the joint coordinatesof the robotic arm 101 and the common coordinate system of the motiontracking system 105, which may enable the position and orientation ofthe end effector 102 of the robotic arm 101 to be controlled withrespect to the patient 200.

In addition to passive marker devices described above, the motiontracking system 105 may alternately utilize active marker devices thatmay include radiation emitters (e.g., LEDs) that may emit radiation thatis detected by an optical sensor device 111. Each active marker deviceor sets of active marker devices attached to a particular object mayemit radiation in a pre-determined strobe pattern (e.g., with modulatedpulse width, pulse rate, time slot and/or amplitude) and/or wavelengthwhich may enable different objects to be uniquely identified and trackedby the motion tracking system 105. One or more active marker devices maybe fixed relative to the patient, such as secured to the patient's skinvia an adhesive membrane or mask. Additional active marker devices maybe fixed to surgical tools 104 and/or to the end effector 102 of therobotic arm 101 to allow these objects to be tracked relative to thepatient.

In further embodiments, the marker devices may be passive maker devicesthat include moiré patterns that may enable their position andorientation to be tracked in three-dimensional space using a singlecamera using Moiré Phase Tracking (MPT) technology. Other trackingtechnologies, such as computer vision systems and/or magnetic-basedtracking systems, may also be utilized.

As shown in FIG. 1 , the optical sensor device 111 may include aplurality of cameras 207 mounted to an arm 209 extending above thepatient surgical area. The arm 209 may be mounted to or above theimaging device 103. The arm 209 may enable the sensor device 111 topivot with respect to the arm 209 and/or the imaging device 103 (e.g.,via one or more ball joints 213). The arm 209 may enable a user toadjust the position and/or orientation of the sensor device 111 toprovide the cameras 207 with a clear view into the surgical field whileavoiding obstructions. The arm 209 may enable the position and/ororientation of the sensor device 111 to be adjusted and then locked inplace during an imaging scan or surgical procedure.

The system 100 may also include at least one display device 119 asillustrated in FIG. 1 . The display device 119 may display image data ofthe patient's anatomy obtained by the imaging device 103. In the case ofCT image data, for example, the display device 119 may display athree-dimensional volume rendering of a portion of the patient's anatomyand/or may display two-dimensional slices (e.g., axial, sagittal and/orcoronal slices) through the 3D CT reconstruction dataset. The displaydevice 119 may facilitate planning for a surgical procedure, such as byenabling a surgeon to define one or more target positions in thepatient's body and/or a path or trajectory into the patient's body forinserting surgical tool(s) to reach a target position while minimizingdamage to other tissue or organs of the patient. The position and/ororientation of one or more objects tracked by the motion tracking system105 may be shown on the display 119, and may be shown overlaying theimage data. The use of tracked surgical instruments or tools incombination with pre-operative or intra-operative images of thepatient's anatomy in order to guide a surgical procedure may be referredto as “image-guided surgery.”

In embodiments, the display device 119 may be a handheld computingdevice, such as a tablet device. One or more handheld display devices119 may be mounted to an arm 209 extending above the patient surgicalarea, as shown in FIG. 1 . The arm 209 may also support the opticalsensing device 111 for the motion tracking system 105, as describedabove. In other embodiments, a handheld display device 119 may bemounted to the patient support 60 or column 50 or to any portion of theimaging system 103, or to any of the wall, ceiling or floor in theoperating room, or to a separate cart. Alternately or in addition, theat least one display device 119 may be a monitor display that may belocated on a mobile cart or mounted to another structure (e.g., a wall)within the surgical theater. In further embodiments, a display device119 may be a head-mounted display that may be worn by a surgeon or otherclinician.

As shown in FIG. 1 , the robotic arm 101 may be fixed to the imagingdevice 103, such as on a support element 215 (e.g., a curved rail) thatmay extend concentrically over the outer surface of the O-shaped gantry40 of the imaging device 103. In embodiments, an arm 209 to which theoptical sensing device 111 is mounted may be mounted to the same or asimilar support element 215 (e.g., curved rail) as the robotic arm 101.The position of the robotic arm 101 and/or the arm 209 may be adjustablealong the length of the support element 215. In other embodiments, therobotic arm 101 may be secured to any other portion of the imagingdevice 103, such as directly mounted to the gantry 40. Alternatively,the robotic arm 101 may be mounted to the patient support 60 or column50, to any of the wall, ceiling or floor in the operating room, or to aseparate cart. Although a single robotic arm 101 is shown in FIG. 1 , itwill be understood that two or more robotic arms 101 may be utilized.Each robotic arm 101 may include an end effector 102 with an adjustableinternal diameter opening, as described in further detail below.

The at least one robotic arm 101 may aid in the performance of asurgical procedure, such as a minimally-invasive spinal surgicalprocedure or various other types of orthopedic, neurological,cardiothoracic and general surgical procedures. In embodiments, themotion tracking system 105 may track the position of the robotic arm 101(e.g., via marker device 202 on end effector 102 as shown in FIG. 1 )within the patient coordinate system. A control loop may continuouslyread the tracking data and the current parameters (e.g., jointparameters) of the robotic arm 101 and may send instructions to arobotic controller to cause the robotic arm 101 to move to a desiredposition and orientation within the patient coordinate system.

In embodiments, a surgeon may use an image-guided surgery system as aplanning tool for a surgical procedure, such as by setting trajectorieswithin the patient for inserting surgical tools, as well as by selectingone or more target locations for a surgical intervention within thepatient's body. The trajectories and/or target locations set by thesurgeon may be saved (e.g., in a memory of a computer device, such ascomputer device 113 shown in FIG. 1 ) for later use during surgery. Inembodiments, the surgeon may be able to select stored trajectoriesand/or target locations using an image guided surgery system, and therobotic arm 101 may be controlled to perform a particular movement basedon the selected trajectory and/or target location. For example, therobotic arm 101 may be moved to position the end effector 102 of therobotic arm 101 into alignment with the pre-defined trajectory and/orover the pre-determined target location. The hollow tube or cannulaextending through the end effector 102 may be used to guide aninstrument 104 into the patient's body along the pre-defined trajectoryand/or to the pre-defined target location.

In addition to a robotic arm 101 as described above, an end effector 102of the present embodiments may be attached to a moveable arm or boom,which may be motor-driven or manually moved. The arm may be moved toposition the end effector 102 at a desired location with respect to thepatient and the arm may be configured to hold its pose during a surgicalintervention.

An embodiment of an end effector 102 having an adjustable-diameterinternal cannula is illustrated in FIGS. 2-6C. The end effector 102 maybe utilized in a system 100 such as shown in FIG. 1 . The end effector102 in this embodiment includes an elongated main body 201 having acentral opening 203 extending through the main body 201. The main body201 may have a generally cylindrical outer shape. In some embodiments,such as shown in FIGS. 2-4 , the main body 201 may have a stepped ortapered outer width (e.g., diameter) along its length, and may be widerat a first end 205 than at a second end 206. Alternately, the outerwidth of the main body 201 may be substantially constant along itslength.

A connecting member 221 (see FIG. 1 ) may extend from a side of the mainbody 201 and may be used to secure the end effector 102 to the end of arobotic arm 101. In embodiments, the main body 201 and the connectingmember 221 may be permanently connected (e.g., integrally-formedcomponents and/or connected by an adhesive or mechanical fasteners). Inother embodiments, the main body 201 and the connecting member 221 maybe separate components that may be joined to form an end effector 102 asshown in FIG. 1 . For example, the connecting member 221 may have anopening (e.g., a cylindrical-shaped opening) extending through theconnector that is sized and shaped to receive the main body 201 withinthe opening. Alternately or in addition, the connecting member 221 andthe main body 201 may have mating features that enable the main body 201to snap onto or otherwise attach to the connecting member 221. In someembodiments, the connecting member 221 may not be utilized, and the mainbody 201 of the end effector 102 may directly attach to the robotic arm101.

The end effector 102 may be a sterile or sterilizable component that maynot need to be draped during surgery. In some embodiments, the endeffector 102 may be attached to a robotic arm 101 over a surgical drapethat covers the arm 101. The end effector 102 may be a single-usedisposable component, or a multi-use component that may be re-sterilized(e.g., autoclavable). The end effector 102 may have a marker device 202(e.g., an array of reflective spheres mounted to a rigid frame) attachedto the end effector 102 to enable the end effector 102 to be tracked bya motion tracking system 105, such as shown in FIG. 1 .

Referring again to FIGS. 2-4 , a collar 223 may be located proximate tothe first end 205 of the main body 201. The collar 223 may include afirst portion 225 that extends over a portion of the outer surface ofthe main body 201 and an end portion 227 that is located over the firstend 205 of the main body 201. The end portion 227 may include an opening229 that is aligned with the central opening 203 extending through themain body 201 of the end effector 102. The first portion 225 of thecollar 223 may also include a ridged/fluted outer surface to enable thecollar 223 to be easily gripped and manipulated.

The collar 223 may be rotatable with respect to the main body 201 of theend effector 102. The rotation of the collar 223 on the main body 201may cause a variation in the internal diameter of the central opening203. For example, the rotation of the collar 223 may drive the extensionand retraction of one or more members (e.g., flutes 231) towards or awayfrom the interior side wall of the main body 201 to increase or decreasea size of a void space within the main body 201 through which a surgicalinstrument or other tool may pass.

An example of a mechanism for adjusting the internal diameter of an endeffector 102 is shown in FIGS. 5-6C. FIG. 5 is a partial cross-sectionview of the end effector 102 taken along line A-A in FIG. 4 . As shownin FIG. 5 , the main body 201 of the end effector 102 includes a flange233 extending from the interior sidewall of the main body 201. A gear235 is located on a first side of the flange 233 and is coupled to aflute 231 located on the opposite side of the flange 233. The rotationof the gear 235 causes the flute 231 to pivot towards and away from theinterior sidewall of the main body 201. The teeth of the gear 235 engagewith corresponding teeth extending on an interior surface 237 of thecollar 223. Thus, as the collar 223 is turned, the flute 231 is pivotedoutwards and inwards with respect to the interior sidewall of the mainbody 201.

The end effector 102 may have a plurality of flutes 231 coupled tocorresponding gears 235 that may similarly pivot out and back withrespect to the main body 201 as the collar 223 is turned to adjust theinternal diameter of the central opening 203. For example, three flutes231 may be equally spaced around the periphery of the main body 201. Theflutes 231 may be pivotable between a first configuration shown in FIG.6A, in which the flutes 231 are positioned against the sidewall of themain body 201 to provide a maximum amount of clearance through thecentral opening 203, and a second configuration shown in FIG. 6B inwhich the flutes 231 are pivoted out to their maximum extent such thattheir tip ends contact one another and the clearance through the centerof the central opening 203 is at its minimal extent. The flutes 231 mayalso be moved to an intermediate configuration between theconfigurations of FIGS. 6A and 6B. For example, FIG. 6C illustrates theflutes 231 pivoted out such that the tip ends of the flutes 231 define acentral opening 203 (i.e., a working channel) having a diameter, d. Atool having a cross-sectional dimension (e.g., diameter) that isapproximately equal to diameter d may be inserted through the centralopening 203. The tool may slide past the flutes 231 along the length ofthe main body 201 and out through the second end 206 of the main body201 (e.g., into the body of a patient). The flutes 231 may guide theadvancement of the tool along a fixed trajectory (e.g., along thecentral axis of the main body 201) and may prevent radial motion of thetool within the main body 201. In some embodiments, the flutes 231 maybe further tightened against a tool located within the main body 201 byrotating the collar 223 so as to fix the longitudinal position of thetool within the main body 201.

Although the embodiment shown in FIGS. 6A-6C includes three flutes 231,it will be understood that other embodiments may include a differentnumber (e.g., 4, 5, 6, etc.) of flutes 231 that may extend and retractwithin the main body 201 to adjust the interior diameter of the opening203 through which a tool/instrument may be inserted. The plurality offlutes 231 may be moveable within the main body 201 using a suitablemechanism, and may be self-centering, as in the embodiment shown inFIGS. 5-6C.

The end effector 102 may also include a locking mechanism that may beengaged to hold the position of the flutes 231 within the main body 201.In the embodiment shown in FIGS. 2-4 , the locking mechanism may be asecond collar 239 (a locking collar) located on the main body 201adjacent to collar 223. The second collar 239 may be engaged to preventcollar 223 from rotating on the main body 201 and may be disengaged toallow the collar 223 to rotate on the main body 201.

In embodiments, the second collar 239 may be engaged to lock therotation of collar 223 by moving the second collar 239 into contact withcollar 223. The second collar 239 may be disengaged by moving the secondcollar 239 out of contact with collar 223. In one embodiment, the secondcollar 239 may be moved into contact with collar 223 to provide aninterference fit between the two collars 223, 239 that prevents collar223 from rotating on the main body 201. Alternately or in addition, thetwo collars 223, 239 may include mating features that engage with oneanother to prevent collar 223 from rotating. In embodiments, the secondcollar 239 may be threaded onto the outer surface of the main body 201,and may be tightened against the collar 223 to prevent the collar 223from rotating, and may be backed away from the collar 223 to allow thecollar 223 to rotate. In an alternative embodiment, the second collar239 may be spring-biased against collar 223 to prevent the collar 223from rotating, and may be pushed away from the collar 223 to allow thecollar 223 to rotate. It will be understood that other mechanisms forlocking and unlocking the collar 223 may also be utilized.

The adjustable-diameter end effector 102 may also include an indicator,such as a dial indicator 241, that provides an indication of theinternal diameter of the central opening 203 through which a tool may beinserted. As shown in FIGS. 2 and 6A-6C, the dial indicator 241 mayinclude a reference indicator 242 that may be fixed to the main body201, such as via a cantilevered arm 243 that extends from the side ofthe main body 201 over the end portion 227 of the collar 223. Graduatedmarkings 247 may be located on the end portion 223 of the collar 223.The markings 247 may be calibrated to indicate the internal diameter ofthe opening 203 as the collar 223 is turned on the main body 201.Rotating the collar 223 in a first direction (e.g., counter-clockwise)may increase the diameter of the opening 203 and rotating the collar 223in a second dimension (e.g., clockwise) may decrease the diameter of theopening 203.

In various embodiments, the end effector 102 may be easily adjusted toaccommodate various-sized surgical instruments/tools that may beinserted through the end effector 102 while maintaining a desiredtrajectory into a patient. Examples of such tools/instruments include,without limitation, a needle, a cannula, an awl, a drill, a screwdriver, a screw, and implant, a tool for gripping or cutting, anelectrode, a radiation source, and an endoscope.

The foregoing method descriptions are provided merely as illustrativeexamples and are not intended to require or imply that the steps of thevarious embodiments must be performed in the order presented. As will beappreciated by one of skill in the art the order of steps in theforegoing embodiments may be performed in any order. Words such as“thereafter,” “then,” “next,” etc. are not necessarily intended to limitthe order of the steps; these words may be used to guide the readerthrough the description of the methods. Further, any reference to claimelements in the singular, for example, using the articles “a,” “an” or“the” is not to be construed as limiting the element to the singular.

The preceding description of the disclosed aspects is provided to enableany person skilled in the art to make or use the present invention.Various modifications to these aspects will be readily apparent to thoseskilled in the art, and the generic principles defined herein may beapplied to other aspects without departing from the scope of theinvention. Thus, the present invention is not intended to be limited tothe aspects shown herein but is to be accorded the widest scopeconsistent with the principles and novel features disclosed herein.

What is claimed is:
 1. An end effector for a surgical robotic system,comprising: a main body supported by a robotic arm and having aninterior sidewall and an opening extending through the main body; one ormore members located within the main body that extend into and retractfrom the opening to vary a diameter of the opening through which a toolmay be inserted; and an adjustment mechanism on the end effector andcoupled to the one or more members for varying the diameter of theopening, the adjustment mechanism comprising a collar coupled to the oneor more members such that rotation of the collar in a first directioncauses the one or more members to move away from the interior sidewallof the main body to reduce the diameter of the opening, and rotation ofthe collar in a second direction causes the one or more members to movetowards the interior sidewall of the main body to increase the diameterof the opening.
 2. The end effector of claim 1, wherein the one or moremembers comprise a plurality of flutes that are pivotable towards andaway from the interior sidewall of the main body to vary the diameter ofthe opening.
 3. The end effector of claim 2, wherein each of the flutesis coupled to a gear that engages with an interior surface of the collarsuch that a rotation of the collar on the main body causes each flute topivot with respect to the main body.
 4. The end effector of claim 2,wherein the plurality of flutes are self-centering.
 5. The end effectorof claim 2, further comprising a locking mechanism that is engageable tohold the positions of the plurality of flutes within the main body. 6.The end effector of claim 5, wherein the collar is a first collar andthe locking mechanism comprises a second collar located over the mainbody.
 7. The end effector of claim 6, wherein the second collar ismoveable on the main body between: a first position in which the secondcollar contacts against the first collar to prevent the first collarfrom rotating relative to the main body, and a second position in whichthe second collar is moved away from the first collar to enable thefirst collar to rotate with respect to the main body.
 8. The endeffector of claim 1, further comprising a dial indicator that providesan indication of the diameter of the opening.
 9. The end effector ofclaim 8, wherein the dial indicator includes a reference indicator fixedto the main body and graduated markings located on the collar.
 10. Theend effector of claim 1, further comprising a connecting member thatextends from a side surface of the main body and attaches to the roboticarm.
 11. The end effector of claim 1, further comprising a marker devicefixed to the end effector that enables the end effector to be trackedusing a motion tracking system.
 12. A method of inserting a tool into abody of a patient, comprising: positioning a main body of an endeffector supported by a robotic arm over the body of the patient suchthat an opening extending through the main body defines a trajectoryinto the body of the patient; using an adjustment mechanism comprising acollar located over the main body and coupled to one or more memberslocated within the main body that extend into and retract from theopening to vary a diameter of the opening through which a tool isinserted to vary a size of a working channel through the opening of theend effector by rotating the collar relative to the main body to movethe one or more members relative to an interior sidewall of the mainbody to vary the size of the working channel such that a diameter of theworking channel corresponds with an outer diameter of the tool; andinserting the tool through the working channel of the end effector alongthe defined trajectory and into the body of the patient.
 13. The methodof claim 12, wherein the size of the working channel is varied byextending and retracting a plurality of members of the adjustmentmechanism.
 14. The method of claim 13, wherein the plurality of membersare extended and retracted using an actuator.
 15. The method of claim14, wherein the actuator comprises a rotatable knob or dial.
 16. Themethod of claim 12, wherein the tool comprises at least one of a needle,a cannula, an awl, a drill, a screw driver, a screw, and implant, a toolfor gripping or cutting, an electrode, a radiation source, and anendoscope.
 17. The method of claim 12, wherein positioning the endeffector comprises controlling the robotic arm to move the end effectorto a position such that the opening extending through the main body isaligned with a pre-defined trajectory into the body of the patient.